A semiconductor device having the present high withstand voltage power device IGBT has at a back surface a p collector layer with boron injected in an amount of approximately 3×1013/cm2 with an energy of approximately 50 KeV to a depth of approximately 0.5 μm, and an n+ buffer layer with phosphorus injected in an amount of approximately 3×1012/cm2 with an energy of 120 KeV to a depth of approximately 20 μm. To control lifetime, a semiconductor substrate is exposed to protons at the back surface. Optimally, it is exposed to protons at a dose of approximately 1×1011/cm2 to a depth of approximately 32 μm as measured from the back surface. Thus snapback phenomenon can be eliminated and an improved low saturation voltage (Vce (sat))-offset voltage (Eoff) tradeoff can be achieved.
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1. A semiconductor device comprising:
a semiconductor element region provided at a front surface of a semiconductor substrate of a first conduction type;
a collector layer of a second conduction type and a buffer layer of said first conduction type provided in said semiconductor substrate in a direction of a depth of said semiconductor substrate as seen from a back surface of said semiconductor substrate; and
a donor layer including a defect layer in said semiconductor substrate at a region located at a depth of approximately 32 μm as measured from the back surface of said semiconductor substrate, wherein
said collector layer includes a region of an impurity of said second conduction type in said semiconductor substrate at a region located from the back surface of said semiconductor substrate to a depth of approximately 0.5 μm, said impurity of said second conduction type being injected in an amount of at most 1×1013/cm2,
said buffer layer contains an impurity of said first conduction type in said semiconductor substrate at a region located at a depth from approximately 0.5 μm to approximately 20 μm as measured from the back surface of said semiconductor substrate, with said impurity of said first conduction type having a concentration with a maximum value of approximately 3×1015/cm3,
said donor layer includes a defect layer formed with a dose of protons of at most 1×1011/cm2 for exposure, and
said amount of said impurity injected in said collector layer and said dose of protons forming said defect layer reducing snapback voltage at low temperatures to be approximately at most 2V.
2. The semiconductor device according to
said maximum value of said impurity concentration of said buffer layer is approximately 150 times an impurity concentration of said semiconductor substrate; and
said maximum value of said impurity concentration of said collector layer is approximately 1,000 times the impurity concentration of said semiconductor substrate.
3. The semiconductor device according to
said donor layer includes a defect layer exposed to protons injected at a dose of approximately at most 2×1011/cm2 into said semiconductor substrate at the back surface, said donor layer having a concentration of approximately at most 7.5×1013/cm3.
4. The semiconductor device according to
5. The semiconductor device according to
6. The semiconductor device according to
said donor layer includes a defect layer containing an impurity concentration having a projecting profile half width of approximately 10 μm to approximately 5 μm that is formed by exposing said semiconductor substrate at a drift region to protons.
7. The semiconductor device according to
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1. Field of the Invention
The present invention relates generally to semiconductor devices and particularly to structures of semiconductor devices that allows a high withstand voltage power device insulated gate bipolar transistor (IGBT) to have an improved electrical characteristic by shallowing a back surface structure and exposing it to protons in an optimized amount to improve low saturation voltage (Vce (sat))-offset voltage (Eoff) tradeoff to allow a semiconductor device having the high withstand voltage power device IGBT for electric power to have a stabilized characteristic and maintain robustness against destruction.
2. Description of the Background Art
For electric railroad applications, inverters and converters are controlled by employing semiconductor devices for electric power that are implemented as IGBT module. For electric railroad applications, high withstand voltage IGBTs mainly of 3.3 KV and 6.5 KV are employed.
A recent new specification required for electric railroad applications is to ensure operation at a low temperature of −55° C. In a conventional specification, for −55° C., low saturation voltage (Vce (sat))'s characteristic waveform is a negative temperature characteristic. Furthermore, current and voltage characteristic waveform is also a negative temperature characteristic.
When an n− type semiconductor substrate is exposed to a large quantity of protons, it has an increased defect layer. The increased defect layer means increased kernels for recombination. This results in a reduced lifetime. Note that minority carriers that are generated or remain recombine with majority carriers and thus disappear. An average time elapsing before they disappear is referred to as a lifetime. More correctly, it is referred to as a lifetime of minority carriers.
Lifetime indicates a positive temperature characteristic. Accordingly, for lower temperature, lifetime is further reduced and snapback phenomenon is increased. In other words, when an n− type semiconductor substrate is exposed to a large quantity of protons, a phenomenon similar in terms of lifetime to reduction in temperature will manifest.
Snapback phenomenon is determined by a product of injection efficiency by transport factor. If the product is small, a large snapback phenomenon manifests. Injection efficiency is determined by a difference in temperature of a pn junction of a back surface of the semiconductor substrate. Transport factor is determined by lifetime, an n− layer's thickness, the semiconductor substrate's inherent impurity concentration, and the like.
If the n− layer's thickness is large and the semiconductor substrate's inherent impurity concentration is small, a smaller transport factor is provided. When a high withstand voltage power device IGBT with such a small transport factor has a back surface containing an impurity reduced in concentration, snapback phenomenon more readily occurs. Accordingly it is important to expose the semiconductor substrate at the back surface to protons in an amount to control lifetime (or transport factor).
In contrast, for increased temperature, increased lifetime is provided. This is because high temperature provides an increased probability that minority carriers that have once recombined and thus disappeared are regenerated by thermal energy, resulting in increased, generated carriers. Accordingly, residual carriers increase, and a phenomenon similar to effectively increased lifetime will manifest. Japanese Patent Laying-open No. 2002-299623 discloses a high withstand voltage power device IGBT.
An issue to be addressed by the present invention lies in that a conventional high withstand voltage power device IGBT requires controlling the amount of holes injected from a p type collector region that is required for an operation of a MOS (Metal-Oxide-Semiconductor) unit cell formed at a major surface thereof.
Therefore the present invention contemplates a semiconductor device having a high withstand voltage power device IGBT that has a structure that can achieve an improved tradeoff characteristic and maintain and improve robustness against destruction that is possibly attributed to an influence of invalid carriers by properly controlling the amount of holes injected from a p type collector region.
Furthermore, it also lies in providing a semiconductor device having a structure that can prevent variation in low saturation voltage (Vce (sat)) and reduce or prevent snapback phenomenon at a low temperature of −55° C. by exposing a semiconductor substrate at a back surface to protons in an optimized amount.
A semiconductor substrate as based on the present invention includes: a semiconductor element region provided at a front surface of a semiconductor substrate of a first conduction type; and a collector layer of a second conduction type and a buffer layer of the first conduction type provided in the semiconductor substrate in a direction of a depth of the semiconductor substrate as seen from a back surface of the semiconductor substrate. The collector layer includes a region of an impurity of the second conduction type in the semiconductor substrate at a region located from the back surface to a depth of approximately 0.5 μm, with the impurity of the second conduction type having a concentration with a maximum value of approximately 2×1016/cm3. The buffer layer contains an impurity of the first conduction type in the semiconductor substrate at a region located at a depth from approximately 0.5 μm to approximately 20 μm as measured from the back surface of the semiconductor substrate, with the impurity of the first conduction type having a concentration with a maximum value of approximately 3×1015/cm3. A donor layer including a defect layer in the semiconductor substrate at a region located at a depth of approximately 32 μm as measured from the back surface is provided.
The present invention can provide a semiconductor substrate in which collector and buffer layers' respective concentrations and depths, and a donor layer of a defect layer that contains an impurity having a concentration having a projecting profile can be combined together to provide a high withstand voltage power device IGBT having an improved low saturation voltage (Vce (sat))-offset voltage (Eoff) tradeoff characteristic.
Furthermore, there can be provided a 3.3 KV-Planaer-IGBT having a semiconductor substrate having a back surface that has a pn structure containing an impurity controlled in concentration and diffused to a depth, as controlled, and is exposed to protons in a controlled amount to eliminate snapback phenomenon of low saturation voltage Vce (sat) for operation at a low temperature of −55° C. to reduce variation in low saturation voltage Vce (sat) and stabilize a loss of a switching characteristic.
Furthermore, the robustness against destruction of an IGBT module in an individual operation can also be improved. A semiconductor substrate can thus have a back surface that has a p type collector layer and an n type buffer layer having their respective impurities controlled in concentration and depth and is exposed to protons for a donor layer in a controlled amount to provide a high withstand voltage power device IGBT as a product ranging from high to low speed applications.
The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
Hereinafter reference will be made to the drawings to describe a structure of a semiconductor device in an each embodiment of the present invention.
With reference to
An n− type semiconductor substrate 100 has a back surface provided with a p type collector layer 4 and an n+ type buffer layer 5. N− type semiconductor substrate 100 has a front surface provided at a center with a MOS cell region 1. MOS cell region 1 underlies gate electrode 110 with a gate insulation film (not shown) posed therebetween.
Furthermore, MOS cell region 1 is surrounded by a guard ring region 2. More specifically, n− type semiconductor substrate 100 has a front surface provided with a plurality of p type wells 3 that configure a guard ring annularly to surround MOS cell region 1. P type well 3 underlies a field oxide film 310 and an interlayer insulation film 320.
Maintaining a high withstand voltage power device IGBT's characteristic in withstand voltage requires optimizing n− type semiconductor substrate 100 in thickness and specific resistance. The present embodiment employs a 3.3 KV high withstand voltage power device IGBT implemented by a floating zone (FZ) wafer with n− type semiconductor substrate 100 having a thickness of approximately 320 μm to approximately 380 μm, and a specific resistance of approximately 220 Ωcm to approximately 280 Ωcm.
MOS cell region 1 provided at a major surface of n− type semiconductor substrate 100 adopts a conventional flat type DMOS (Double diffused Metal Oxide Semiconductor) structure. Guard ring region 2 surrounding MOS cell region 1 has p type wells 3 formed in a ring surrounding a chip of MOS cell region 1, and field oxide film 310 and interlayer insulation film 320, as has been described above, forming a multilayer structure serving as a protection film. P type well 3 serves to each maintain a withstand voltage of approximately 200 V. For higher withstand voltage, more p type wells 3 will be provided.
In the present embodiment, the high withstand voltage power device IGBT's back surface structure is important. In a conventional IGBT fabrication method, a back surface structure (p+/n+/n− structure) is formed prior to a major surface's MOS structure. After the back surface structure is formed, the major surface is polished and a fractured layer is removed, and a MOS cell region and a guard ring region are formed. Furthermore, a conventional IGBT has a p+ collector layer having an impurity of high concentration, with the impurity diffused deep. Furthermore, an n+ type buffer layer also has an impurity of high concentration.
More specifically, a conventional back surface structure has a p+ collector layer with boron (B) injected in an amount of approximately 4.0×1015/cm2 with an energy of approximately 50 KeV to a depth of approximately 5.0 μm, and an n+ type buffer layer with phosphorus (P) injected in an amount of approximately 3.3×1014/cm2 with an energy of approximately 2.80 KeV to a depth of approximately 20 μm, and is exposed to protons in an amount of approximately 3×1011/cm2 to approximately 5×1011/cm2.
In the present embodiment the back surface structure has an n+ type buffer layer formed before the major surface has a MOS structure, as conventional. However, the back surface structure has a p type collector layer that is formed in a later process and is shallow. This fabrication method has a feature, which will be described later.
In the present embodiment, the back surface has p type collector layer 4 with boron (B) injected in an amount of approximately 3×1013/cm2 with an energy of approximately 50 KeV to a depth of approximately 0.5 μm, and an n+ type buffer layer with phosphorus (P) injected in an amount of approximately 3×1012/cm2 with an energy of approximately 120 KeV to a depth of approximately 20 μm.
Furthermore, to control lifetime, the semiconductor substrate is exposed to protons. Optimally, it is exposed to protons in an amount of approximately 1×1011/cm2 to a depth of approximately 32 μm from the back surface. This can prevent snapback phenomenon and achieve an improved low saturation voltage (Vce (sat))-offset voltage (Eoff) tradeoff.
Conventional IGBT does not require to ensure operation at low temperature. As such, it had not been found that variation in low saturation voltage Vce (sat) is caused by snapback phenomenon. Accordingly in present embodiment it is noted that a cause of variation in low saturation voltage Vce (sat) causes snapback phenomenon, and a high withstand voltage power device IGBT can be provided that has a back surface optimized in structure and exposed to protons in an optimized amount to minimize snapback phenomenon and provide an improved low saturation voltage (Vce (sat))-offset voltage (Eoff) tradeoff.
As shown in
By this structure, a hot leakage current has implemented approximately 100 μA/cm2 in an IGBT of a 3.3 KV, high withstand voltage specification. As p type collector layer 4 is reduced in thickness from a conventional, approximately 400 μm to approximately 350 μm, low saturation voltage Vce (sat) is also reduced. N− type semiconductor substrate 100 having holes injected thereinto in an optimized amount can further be exposed to protons in an optimized amount to obtain a high withstand voltage power device IGBT that can achieve a stabilized low saturation voltage Vce (sat)-offset voltage (Eoff) tradeoff characteristic.
As shown in
For example, as based on the profile in concentration indicated in
Furthermore, exposing semiconductor substrate 100 at a drift region to protons, as shown in
Furthermore, a dose of protons of approximately 2×1011/cm2 for exposure and protons' projected range (Rp) set at the depth of buffer layer 5 plus approximately 10 μm (Rp=42 μm) also provided a defect layer containing an impurity having a concentration having a projecting profile having a half width of approximately 10 μm.
Thus a high withstand voltage power device IGBT can be provided that exhibits a stabilized low saturation voltage Vce (sat)-offset voltage (Eoff) tradeoff characteristic.
From a result of the experiment, it is determined that the Vcc range is controlled to be approximately at most 2 V and that a dose of protons for exposure is controlled up to approximately 2×1011/cm2. If p type collector layer 4 has a concentration (or boron (B) injected in an amount) of approximately 1×1013/cm2 [a Specification B], snapback phenomenon appears for a dose of protons for exposure equivalent to approximately 1×1011/cm2.
If p type collector layer 4 has a concentration (or boron (B) injected in an amount) of approximately 5×1013/cm2 [a specification C], snapback phenomenon appears for a dose of protons for exposure equivalent to approximately 5×1011/cm2. Thus, a dose of protons for exposure can be controlled in a range of approximately 1×1011/cm2 to approximately 5×1011/cm2. If p type collector layer 4 has a concentration (or boron (B) injected in an amount) of approximately 3×1013/cm2 [a specification A], snapback phenomenon appears for a dose of protons for exposure equivalent to approximately 3×1011/cm2.
Thus for the above [specification C], a dose of protons for exposure can be controlled in a wide range from approximately 1×1011/cm2 to approximately 5×1011/cm2. N− type semiconductor substrate 100 having a back surface that has p type collector layer 4 controlled in structure and is exposed to protons in a controlled amount thus allows a high withstand voltage power device IGBT to exhibit a stabilized low saturation voltage Vce (sat)-offset voltage (Eoff) tradeoff characteristic, as desired by customers.
An example with an Al absorber of approximately 135 μm in thickness, protons' projected range (Rp) of approximately 32 μm, and a dose of protons of approximately 1×1011/cm2 for exposure, and an example with an Al absorber of approximately 115 μm in thickness, protons' projected range (Rp) of approximately 52 μm, and a dose of protons of approximately 5×1010/cm2 for exposure provide equivalent (withstand voltage or like IGBT) characteristics. From this result, a control range avoiding snapback phenomenon for −55° C. is set.
Note that donor layer 6, as shown in
In
Protons' projected range (Rp) corresponds to a position of exposure proposed in the present embodiment. It is a position of approximately 32 μm measured from the back surface. For 25° C. (room temperature) and 125° C., snapback phenomenon is not observed, and variation in low saturation voltage Vce is not noticed. In the present embodiment, optimization is done to also prevent snapback phenomenon for −55° C.
An F5#01-11 high withstand voltage power device IGBT received a dose of protons of approximately 5×1010/cm2 for exposure. An F5#03-11 high withstand voltage power device IGBT received a dose of protons of approximately 1×1011/cm2 for exposure. An F5#05-11 high withstand voltage power device IGBT received a dose of protons of approximately 2×1011/cm2 for exposure. An F5#07-11 high withstand voltage power device IGBT received a dose of protons of approximately 3×1011/cm2 for exposure. An F5#09-11 high withstand voltage power device IGBT received a dose of protons of approximately 5×1011/cm2 for exposure. An F5#11-11 high withstand voltage power device IGBT received a dose of protons of approximately 7×1011/cm2 for exposure. With such different doses of protons for exposure, the low saturation voltage Vce (sat)-offset voltage (Eoff) tradeoff characteristic exhibits a relationship, as shown in
With reference to
Thus the present embodiment provides a high withstand voltage power device IGBT, as shown in
Thus, combining a pn concentration and a depth, and donor layer 6 formed in a defect layer and containing an impurity having a concentration having a projecting profile together can provide a high withstand voltage power device IGBT exhibiting an improved low saturation voltage (Vce (sat))-offset voltage (Eoff) tradeoff characteristic. Furthermore, a 3.3 KV-Planaer-IGBT including a semiconductor substrate having a back surface that has a pn structure containing an impurity controlled in concentration and depth and is exposed to protons in a controlled amount can eliminate snapback phenomenon of low saturation voltage Vce (sat) for operation at a low temperature of −55° C., and thus reduce variation in low saturation voltage Vce (sat) and stabilize a loss of a switching characteristic.
Method of Fabrication
A semiconductor element of a 3.3 KV, high withstand voltage power device IGBT (an insulated gate bipolar transistor in particular) for electric power that has the
The high withstand voltage power device IGBT described in the Background Art section is fabricated in a method generally including: lot formation, a back surface n type buffer diffusion step, a back surface p type collector diffusion step, a p type well formation step, a gate (1) formation step, a gate (2) formation step, a channel dope step, a p+ type impurity diffusion step, a source formation step, a contact (1) formation step, an aluminum interconnection (1) step, a glass coating step, a 4 layer vapor deposition (Al/Mo/Ni/Au) step, a lifetime control step (of a high speed type), and an annealing step.
In contrast, the present embodiment provides a high withstand voltage power device IGBT fabricated in a method different from the method employed in the Background Art. More specifically, the latter method initially forms the p+ type collector layer/n+ type buffer layer of the back surface by thermal diffusion, whereas the former method starts with a p type well formation step, and in a glass coating step and the following steps, adopts n type buffer and p type collector layer formation steps of a process for the back surface.
For example, it includes lot formation, a back surface n type buffer diffusion step (obtaining a lower concentration), a p type well formation step, a gate (1) formation step, a gate (2) formation step, a channel dope step, a p+ type impurity diffusion step, a source formation step, a back surface p type collector diffusion step (shallowing, and obtaining a lower concentration), a contact (1) formation step, an aluminum interconnection (1) step, a glass coating step, a 4 layer vapor deposition (Al/Mo/Ni/Au) step, and a lifetime control step (low lifetime control).
Hereinafter reference will be made to
With reference to
N− type semiconductor substrate 100 has its entire surface undergoing an oxidization step, and from the back surface, phosphorus is injected. This forms n+ type buffer layer 5 from the substrate's surface to a depth of tens μm. In the present embodiment, phosphorus (P) is injected in an amount of approximately 3×1012/cm2 with an energy of approximately 120 KeV to a depth of approximately 20 μm to form n+ type buffer layer 5.
With reference to
With reference to
Then with reference to
Subsequently, a resist film 54 is deposited on n− type semiconductor substrate 100 and photolithography is employed to selectively form an opening 54a in MOS cell region 1. Subsequently through opening 54a phosphorus is injected in MOS cell region 1 at a surface of n− type semiconductor substrate 100 into a shallow region. Subsequently, n− type semiconductor substrate 100 is heated to diffuse the phosphorus. Thus MOS cell region 1 is provided with an n type well 12.
Then, with reference to
Then, with reference to
Then, with reference to
Then, with reference to
Then, with reference to
Then, with reference to
Then, with reference to
Then, with reference to
Then, with reference to
Thus, combining a pn concentration and a depth, and donor layer 6 of a defect layer that contains an impurity having a concentration having a projecting profile together can provide a high withstand voltage power device IGBT exhibiting an improved low saturation voltage (Vce (sat))-offset voltage (Eoff) tradeoff characteristic. Furthermore, a 3.3 KV-Planaer-IGBT including a semiconductor substrate having a back surface that has a pn structure containing an impurity controlled in concentration and depth and is exposed to protons in a controlled amount can eliminate snapback phenomenon of low saturation voltage Vce (sat) for operation at a low temperature of −55° C., and thus reduce variation in low saturation voltage Vce (sat) and stabilize a loss of a switching characteristic.
Note that in the above embodiment the back surface electrode's p+ collector layer 4 and n+ type buffer layer 5 have their impurities fixed in concentration and a lifetime control layer is selected to allow a tradeoff characteristic to be variable to accommodate more applications. Alternatively, varying p+ collector layer 4 in concentration can also provide an equivalent tradeoff characteristic.
Furthermore, a gettering technique that can be developed commonly for any wafers has also been established as a technique of management that prevents a difference between materials for silicon and a difference between processes in level of contamination from affecting a characteristic. Conventionally, the back surface structure could not have a p type collector's concentration and an n type buffer layer controlled in profile. The technique allows such control, and holes can be injected in an optimized amount.
The low lifetime control layer that has been added has provided the tradeoff characteristic with more options. Switching loss reduction, and a switching characteristic's off loss (turn off loss) (Eoff)-on voltage (Vce (sat)) tradeoff characteristic can be repeated as aimed. The amount of hoes that has been optimized has also improved withstand voltage.
Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the scope of the present invention being interpreted by the terms of the appended claims.
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